CN217065205U - Multifunctional automatic noodle processing equipment - Google Patents

Abstract

The utility model discloses a multi-functional noodless automatic processing equipment, include flour-mixing machine assembly, conveyer belt, whitewashed mechanism, calendering mechanism, cut the mechanism and decide the mechanism, the conveyer belt sets up the discharge end at the flour-mixing machine assembly, whitewashed mechanism, calendering mechanism, cut the mechanism and decide the direction of delivery that the mechanism followed the conveyer belt and set gradually, just whitewashed mechanism is located the upper reaches of flour-mixing machine assembly discharge gate, calendering mechanism, cut the mechanism and decide the low reaches that the mechanism is located the flour-mixing machine assembly discharge gate. The utility model realizes the integrated production and processing of noodles through the rolling mechanism, the splitting mechanism, the cutting mechanism and the collecting vehicle, reduces the manual links, improves the production efficiency and can ensure the cleanness and sanitation of products; in addition, can spill the flour on the conveyer belt automatically through applying the mechanism of flour, prevent the noodless adhesion on the conveyer belt, guaranteed the normal production processing of noodless.

Description

Multifunctional automatic noodle processing equipment

Technical Field

The utility model relates to a noodless production technical field, in particular to multi-functional noodless automatic processing equipment.

Background

At present, the production and processing modes of the noodles are generally two types:

one is a manual mode, namely, the fabric is pressed into a wrapper by using simple instruments manually, then powder is spread and cut manually, and finally the wrapper is collected and aired. However, this method is not only inefficient and low in yield, but also has the problem of product contamination due to human factors during the production process, and is not suitable for large-scale production.

The other is a mechanical mode, namely, the dough kneading, dough kneading and extrusion are automatically carried out by a special noodle maker, the formed noodles are directly produced, and then the formed noodles are manually collected and aired. Although the efficiency of the production mode is improved to a certain degree compared with that of a manual production mode, the whole production flow is not completely connected, and the automation degree is lower.

In addition, since the noodles have a certain viscosity immediately after production, a layer of flour needs to be manually sprinkled on the conveyor belt to prevent the noodles from being stuck on the conveyor belt, but the manual sprinkling efficiency is low and the uniformity is poor, so that further improvement is needed.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the utility model discloses a multifunctional automatic noodle processing device, which comprises a flour-mixing machine assembly, a conveyor belt, a flour applying mechanism, a rolling mechanism, a cutting mechanism and a cutting mechanism, wherein the conveyor belt is arranged at the discharge end of the flour-mixing machine assembly, the flour applying mechanism, the rolling mechanism, the cutting mechanism and the cutting mechanism are sequentially arranged along the conveying direction of the conveyor belt, the flour applying mechanism is positioned at the upstream of a discharge port of the flour-mixing machine assembly, and the rolling mechanism, the cutting mechanism and the cutting mechanism are positioned at the downstream of the discharge port of the flour-mixing machine assembly;

the flour applying mechanism comprises a flour box, a stirring roller and a brush roller, wherein the flour box is supported and arranged above the feeding end of the conveying belt, the stirring roller is arranged at the discharging port of the flour box and is connected with the conveying belt in a synchronous transmission mode, and the brush roller is arranged on one side of the flour box and is connected with the conveying belt in a synchronous transmission mode.

Furthermore, a plurality of stirring rods are arranged on the outer circumferential surface of the stirring roller at equal intervals.

Furthermore, the discharge opening of the flour box is provided with a discharge plate, and the discharge plate is provided with a plurality of discharge holes.

Further, the calendering mechanism includes one-level calendering roller, second grade calendering roller and tertiary calendering roller, one-level calendering roller, second grade calendering roller and tertiary calendering roller interval set up in the conveyer belt top, just the roll body diameter of one-level calendering roller, second grade calendering roller and tertiary calendering roller reduces in proper order.

Further, cut the mechanism including dividing the roller and cutting the motor, divide and cut the roller setting and just be connected with cutting motor drive in the conveyer belt top, divide and cut and be equipped with a plurality of slitting blades along its axis direction equidistance interval on the roller.

Further, decide the mechanism and include the support frame, decide sword, drive carousel and decide the motor, it passes through the support frame setting in the conveyer belt top to decide the motor, the drive carousel with decide motor drive and be connected, decide about sword both ends and the support frame sliding connection and through connecting rod and drive carousel eccentric connection.

Further, the support frame side is equipped with the slide rail along vertical direction, be equipped with the slider on the slide rail, decide the fixed setting of sword on the slider, connecting rod one end is rotated with the slider and is connected, and the other end rotates with the drive carousel and is connected.

Further, the side of the conveyor belt is provided with a transverse adjusting groove, the bottom of the support frame is provided with an adjusting block, and the adjusting block is arranged in the transverse adjusting groove through a locking bolt.

Furthermore, the discharge end of conveyer belt still is equipped with the collection vehicle, be equipped with vertical support on the collection vehicle, the upper and lower both ends of vertical support respectively are equipped with a sprocket, and two sprockets are connected through the drive chain transmission, and the sprocket that is located vertical support lower extreme is connected with the collection motor transmission, the drive chain side rotates and is provided with a plurality of collection boards.

Furthermore, a longitudinal rack is arranged on one side, close to the collecting plate, of the longitudinal support, a gear is arranged at the joint of the collecting plate and the transmission chain, and the gear is meshed with the longitudinal rack.

The utility model has the advantages that:

the multifunctional automatic noodle processing equipment realizes integrated production and processing of noodles through the rolling mechanism, the splitting mechanism, the cutting mechanism and the collecting vehicle, reduces manual links, improves production efficiency and can ensure cleanness and sanitation of products; in addition, can spill the flour on the conveyer belt automatically through applying the mechanism of flour, prevent the noodless adhesion on the conveyer belt, guaranteed the normal production processing of noodless.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to these drawings without inventive labor.

Fig. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic structural view of the discharging mechanism of the present invention;

FIG. 3 is a schematic structural view of a powder applying mechanism of the present invention;

fig. 4 is a schematic structural view of a calendering mechanism according to the present invention;

fig. 5 is a schematic structural view of the center slitting mechanism of the present invention;

FIG. 6 is a schematic structural view of a cutting mechanism according to the present invention;

fig. 7 is a schematic structural view of the collecting vehicle of the present invention;

fig. 8 is a partial enlarged view of a portion a in fig. 7.

Reference numerals:

10-a dough mixer assembly;

20-a conveyor belt; 21-a transverse adjustment groove; 22-a regulating block; 23-a locking bolt;

30-a powder applying mechanism; 31-flour box; 32-a stirring roller; 33-a brush roller; 34-a stirring rod; 35-a discharge plate;

40-a calendering mechanism; 41-primary calendering roll; 42-secondary calendering rolls; 43-three-stage calendering rolls; 44-powder supplement box;

50-a splitting mechanism; 51-slitting roller; 52-a slitting motor; 53-slitting blade;

60-cutting mechanism; 61-a support frame; 62-cutting off the knife; 63-driving the turntable; 64-cutting the motor; 65-connecting rod; 66-a slide rail; 67-a slide block;

70-a collection vehicle; 71-longitudinal support; 72-a sprocket; 73-a drive chain; 74-a collection motor; 75-a collection plate; 76-longitudinal rack; 77-gear;

80-a frame;

90-driving the motor;

100-a driving wheel;

110-a driven wheel; 111-a first drive wheel; 112-a second transmission wheel; 113-a first transmission member; 114-a second transmission;

120-a blanking sliding plate;

130-a stirring mechanism;

140-a discharge mechanism; 141-cylinder body; 142-auger; 143-feed inlet; 144-discharge hole.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

It should be noted that all the directional indicators (such as upper, lower, left, right, front and rear … …) in the embodiment of the present invention are only used to explain the relative position relationship between the components, the motion situation, etc. in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indicator is changed accordingly.

In the description of the embodiments, the terms "disposed," "connected," and the like are to be construed broadly unless otherwise explicitly specified or limited. For example, the connection can be fixed, detachable or integrated; can be mechanically or electrically connected; either directly or through an intervening medium, or through internal communication between two elements. The specific meaning of the above terms in the present invention can be understood as a specific case by those skilled in the art.

As shown in fig. 1, the automatic multifunctional noodle processing device of the present embodiment includes a dough mixer assembly 10, a conveyor belt 20, a noodle applying mechanism 30, a rolling mechanism 40, a slitting mechanism 50, a cutting mechanism 60 and a collecting cart 70, wherein the conveyor belt 20 is disposed at a discharge end of the dough mixer assembly 10, the noodle applying mechanism 30, the rolling mechanism 40, the slitting mechanism 50 and the cutting mechanism 60 are sequentially disposed along a conveying direction of the conveyor belt 20, the noodle applying mechanism 30 is located at an upstream of a discharge port of the dough mixer assembly 10, the rolling mechanism 40, the slitting mechanism 50 and the cutting mechanism 60 are located at a downstream of the discharge port of the dough mixer assembly 10, and the collecting cart 70 is disposed at the discharge end of the conveyor belt 20.

The conveyor belt 20 is arranged on the frame 80, the drive motor 90 is arranged on the frame 80, the two ends of the frame 80 are respectively provided with the driving wheel 100 and the driven wheel 110, the driving wheel 100 and the driven wheel are in transmission connection through the conveyor belt 20, and the drive motor 90 is in transmission connection with the driving wheel 100 through a transmission belt or a transmission chain; the driving pulley 100 and the driven pulley 110 may be pulleys or sprockets.

The upper part of the dough mixer assembly 10 is provided with a stirring mechanism 130, a stirring roller is arranged in the stirring mechanism 130, a discharge port of the stirring mechanism 130 is connected with a feed port of the dough mixer assembly 10, and auxiliary materials such as vegetables, eggs, fruits, coarse cereals and the like are added into the stirring mechanism 130, so that noodles with different tastes can be processed.

As shown in fig. 2, the discharging end of the dough kneading machine assembly 10 is provided with a discharging mechanism 140, which comprises a cylinder 141, an auger 142, a feeding port 143 and a discharging port 144, wherein the feeding port 143 and the discharging port 144 are respectively arranged at two ends of the cylinder 141, the feeding port 143 is connected with the discharging end of the dough kneading machine assembly 10, the auger 142 is axially arranged inside the cylinder 141, and one end of the auger is driven to rotate by a motor. The discharge port 143 is provided at the bottom of the other end of the cylinder 141, and the kneaded dough is conveyed to the discharge port 143 by the auger 142 and falls onto the conveyor 20 from the discharge port 143.

As shown in fig. 3, the flour applying mechanism 30 includes a flour box 31, a stirring roller 32 and a brush roller 33, the flour box 31 is supported and arranged above the feeding end of the conveyor belt 20, the stirring roller 32 is arranged at the discharging port of the flour box 31 and is in synchronous transmission connection with the conveyor belt 20, and the brush roller 33 is arranged at one side of the flour box 31 and is in synchronous transmission connection with the conveyor belt 20.

Specifically, the driven wheel 110 is coaxially provided with a first transmission wheel 111 and a second transmission wheel 112, the first transmission wheel 111 is in transmission connection with the stirring roller 32 through a first transmission piece 113, and the second transmission wheel 112 is in transmission connection with the brush roller 33 through a second transmission piece 114. The first transmission wheel 111 and the second transmission wheel 112 may be belt wheels or chain wheels, and the first transmission member 113 and the second transmission member 114 may be belts or chains.

A plurality of stirring rods 34 are arranged on the outer circumferential surface of the stirring roller 33 at equal intervals, a discharging plate 35 is arranged at the discharging port of the flour box 31, and a plurality of discharging holes are formed in the discharging plate 35.

The dough mixer assembly 10 adopts the existing dough mixing and kneading integrated equipment on the market, the discharging mechanism 140 conveys the kneaded dough to the conveyor belt 20, and the flour is uniformly sprinkled on the conveyor belt 20 in advance through the flour applying mechanism 30, so that the dough is prevented from being adhered to the conveyor belt 20. The concrete powder spraying process comprises the following steps: the driven wheel 110 drives the stirring roller 32 to rotate through the first transmission member 113, the flour in the flour box 31 is scattered through the stirring rod 34, the flour is prevented from being piled or caked, the scattered flour falls onto the conveyor belt 20 through the discharging hole in the discharging plate 35, and the flour is further uniformly laid on the conveyor belt 20 through the brush roller 33.

The calendering mechanism 40 comprises a first-stage calendering roller 41, a second-stage calendering roller 42 and a third-stage calendering roller 43, wherein the first-stage calendering roller 41, the second-stage calendering roller 42 and the third-stage calendering roller 43 are arranged above the conveyor belt 20 at intervals; the roll body diameters of the first-level calendering roll 41, the second-level calendering roll 42 and the third-level calendering roll 43 are sequentially reduced, the distance between the three calendering rolls and the conveying belt 20 is also sequentially reduced, the dough is preliminarily pressed into a thick cake through the first-level calendering roll 41, the cake is further thinned through the second-level calendering roll 42, and finally the cake is calendered into a pancake shape with required thickness through the third-level calendering roll 43.

The three calendering rollers are respectively driven by a motor, and the rotating speed of the three calendering rollers is the same as the rotating speed of the conveyor belt 20, so that the uniform stress of the upper surface and the lower surface is ensured when the dough enters the calendering mechanism 40.

A powder supplement box 44 is arranged above all the three calendering rolls, for example, the primary calendering roll 41 is taken as an example, as shown in fig. 4, the powder supplement box 44 is supported and arranged above the primary calendering roll 41, and the primary calendering roll 41 is partially arranged in the powder supplement box 44. In the rotation process of the primary calender roll 41, the flour in the flour supplement box 44 is adhered to the surface of the roll body, and in the calendering process, the flour is brought to the upper surface of the dough, so that the adhesion of the dough and the roll body is prevented.

After the rolling is completed, the dough cake enters the slitting mechanism 50, as shown in fig. 5, the slitting mechanism 50 includes a slitting roller 51 and a slitting motor 52, the slitting roller 51 is disposed above the conveyor belt 20 and is in transmission connection with the slitting motor 52, and a plurality of slitting blades 53 are disposed on the slitting roller 51 at equal intervals along the axial direction of the slitting roller.

The slitting motor 52 drives the slitting roller 51 to rotate, and the noodle cake is cut into a plurality of thin strips through the slitting blade 53, so that the primary molding of the noodles is completed.

As shown in fig. 6, the cutting mechanism 60 includes a support frame 61, a cutting blade 62, a driving turntable 63, and a cutting motor 64, the cutting motor 64 is disposed above the conveyor belt 20 via the support frame 61, the driving turntable 63 is connected to the cutting motor 64 in a transmission manner, and both ends of the cutting blade 62 are connected to the support frame 61 in a vertically sliding manner and are eccentrically connected to the driving turntable 63 via a connecting rod 65.

Support frame 61 side is equipped with slide rail 66 along vertical direction, is equipped with slider 67 on the slide rail 66, decides sword 62 and be the sheet structure, and both ends are fixed to be set up on slider 67, and connecting rod 65 one end is rotated with slider 67 and is connected, and the other end rotates with drive carousel 63 to be connected.

The cutting motor 64 drives the driving turntable 63 to rotate, and drives the cutting knife 62 to reciprocate up and down through the connecting rod 65, so that the continuous noodles are cut into a plurality of equal-length noodles.

The lateral surface of the conveyor belt 20 is provided with a transverse adjusting groove 21, the bottom of the supporting frame 61 is provided with an adjusting block 22, and the adjusting block 22 is arranged in the transverse adjusting groove 21 through a locking bolt 23. The position of the supporting frame 61 on the conveyor 20 can be adjusted by sliding the adjusting block 22 left and right, thereby adjusting the cutting position of the noodles.

As shown in fig. 7, the collecting cart 70 is provided with a longitudinal support 71, the upper end and the lower end of the longitudinal support 71 are respectively provided with a chain wheel 72, the two chain wheels 72 are in transmission connection through a transmission chain 73, and the chain wheel 72 at the lower end of the longitudinal support 71 is in transmission connection with a collecting motor 74.

The side surface of the transmission chain 73 is rotatably provided with a plurality of collecting plates 75, one side of the longitudinal support 71 close to the collecting plates 75 is provided with a longitudinal rack 76, the joint of the collecting plates 75 and the transmission chain 73 is provided with a gear 77, and the gear 77 is meshed with the longitudinal rack 76.

When the collection motor 74 drives the transmission chain 73 to move downwards, the collection plate 75 follows the transmission chain 73 to move downwards, and the gear 77 rotates anticlockwise under the cooperation of the gear 77 and the longitudinal rack 76, so that the collection plate 75 turns downwards, as shown in fig. 8. When the collecting plate 75 moves to the discharging slide plate 120 at the discharging end of the conveyor belt 20, the collecting plate 75 just coincides with the inclination angle of the discharging slide plate 120, and the noodles slide into the collecting plate 75 from the discharging slide plate 120. Through the mode, the noodles sequentially enter each layer of collecting plate, and the noodle collecting work is completed. After the noodle collection is completed, the worker pushes the collection cart 70 away and replaces the next collection cart. The collected noodles can be eaten as fresh noodles, and can also be aired or dried to form fine dried noodles.

The multifunctional automatic noodle processing equipment realizes the integrated production and processing of noodles through the rolling mechanism 40, the splitting mechanism 50, the cutting mechanism 60 and the collecting vehicle 70, reduces the manual links, improves the production efficiency and can ensure the cleanness and sanitation of products; in addition, can spill the flour on conveyer belt 20 automatically through applying powder mechanism 30, prevent the noodless adhesion on conveyer belt 20, guarantee the normal production processing of noodless.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention. In addition, the technical solutions between the various embodiments can be combined with each other, but must be based on the realization of those skilled in the art; when the technical solutions are contradictory or cannot be combined, the combination of the technical solutions should be considered to be absent, and is not within the protection scope of the present invention.

Claims (10)

1. The utility model provides a multi-functional noodless automatic processing equipment which characterized in that: the automatic powder applying and cutting device comprises a flour-mixing machine assembly, a conveyor belt, a powder applying mechanism, a rolling mechanism, a cutting mechanism and a cutting mechanism, wherein the conveyor belt is arranged at the discharge end of the flour-mixing machine assembly;

the flour applying mechanism comprises a flour box, a stirring roller and a brush roller, wherein the flour box is supported and arranged above the feeding end of the conveying belt, the stirring roller is arranged at the discharging port of the flour box and is connected with the conveying belt in a synchronous transmission mode, and the brush roller is arranged on one side of the flour box and is connected with the conveying belt in a synchronous transmission mode.

2. The automatic multifunctional noodle processing apparatus according to claim 1, wherein: and a plurality of stirring rods are arranged on the outer circumferential surface of the stirring roller at equal intervals.

3. The automatic multifunctional noodle processing apparatus according to claim 2, wherein: the discharge opening department of flour case is equipped with the play flitch, be equipped with a plurality of discharge openings on the play flitch.

4. The automatic multifunctional noodle processing apparatus according to claim 1, wherein: the calendering mechanism comprises a first-level calendering roller, a second-level calendering roller and a third-level calendering roller, wherein the first-level calendering roller, the second-level calendering roller and the third-level calendering roller are arranged above the conveyor belt at intervals, and the diameters of roller bodies of the first-level calendering roller, the second-level calendering roller and the third-level calendering roller are reduced in sequence.

5. The automatic multifunctional noodle processing apparatus according to claim 1, wherein: cut the mechanism including dividing the roller and cutting the motor, divide the roller setting in the conveyer belt top and be connected with cutting motor drive, divide and cut the roller and go up to be equipped with a plurality of slitting blades along its axis direction equidistance interval.

6. The automatic multifunctional noodle processing apparatus according to claim 1, wherein: decide the mechanism and include the support frame, decide sword, drive carousel and decide the motor, it passes through the support frame setting in the conveyer belt top to decide the motor, the drive carousel with decide motor drive and be connected, decide about sword both ends and the support frame sliding connection and through connecting rod and drive carousel eccentric connection.

7. The automatic multifunctional noodle processing apparatus according to claim 6, wherein: the support frame side is equipped with the slide rail along vertical direction, be equipped with the slider on the slide rail, decide the fixed setting of sword on the slider, connecting rod one end is rotated with the slider and is connected, and the other end rotates with the drive carousel and is connected.

8. The automatic multifunctional noodle processing apparatus according to claim 7, wherein: the conveying belt is characterized in that a transverse adjusting groove is formed in the side face of the conveying belt, an adjusting block is arranged at the bottom of the supporting frame, and the adjusting block is arranged in the transverse adjusting groove through a locking bolt.

9. The automatic multifunctional noodle processing apparatus according to claim 1, wherein: the discharge end of conveyer belt still is equipped with the collection vehicle, be equipped with vertical support on the collection vehicle, the upper and lower both ends of vertical support respectively are equipped with a sprocket, and two sprockets are connected through the drive chain transmission, and the sprocket that is located vertical support lower extreme is connected with the collection motor transmission, the drive chain side rotates and is provided with a plurality of collecting plates.

10. The automatic multifunctional noodle processing apparatus according to claim 9, wherein: one side of the longitudinal support, which is close to the collecting plate, is provided with a longitudinal rack, a gear is arranged at the joint of the collecting plate and the transmission chain, and the gear is meshed with the longitudinal rack.

Images